CN106996398A - A kind of inertia-type fluid conveying boosting method and its device - Google Patents
A kind of inertia-type fluid conveying boosting method and its device Download PDFInfo
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- CN106996398A CN106996398A CN201610059427.8A CN201610059427A CN106996398A CN 106996398 A CN106996398 A CN 106996398A CN 201610059427 A CN201610059427 A CN 201610059427A CN 106996398 A CN106996398 A CN 106996398A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04F—PUMPING OF FLUID BY DIRECT CONTACT OF ANOTHER FLUID OR BY USING INERTIA OF FLUID TO BE PUMPED; SIPHONS
- F04F7/00—Pumps displacing fluids by using inertia thereof, e.g. by generating vibrations therein
Abstract
A kind of inertia-type fluid pressurized carrying method and its device, belong to conveying and the supercharging technology field of fluid.The present invention uses a container containing fluid, two through holes being spaced a distance are set on container as fluid input port and fluid outlet, fluid input port and fluid outlet all set the unidirectional input and output flowing of unidirectional valve controls fluid, container vibration is driven using vibratory drive mechanism, make the fluid direction of motion alternate change in container intracavity, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, realize the conveying supercharging of fluid.The present invention realizes the conveying supercharging of fluid, and vibratory drive mechanism only needs small electric energy to maintain the of reciprocating vibration of container during work, and power consumption is small, substantially increases energy-saving effect.
Description
Technical field
The invention belongs to the conveying of fluid and supercharging technology field, especially convey boosting method with a kind of inertia-type fluid and its device is relevant.
Background technology
Common water pump and air pump have two kinds to the principle that the fluids such as liquid or gas are compressed, one kind is displacement pump, by reciprocating motion of the pistons, and piston and the pump housing of this kind of mode need directly to contact and seal, frictional force is larger, another is vane pump, there is strong relative motion by blade rotating boosting, but between blade and fluid, and water pump and air pump are typically electrical energy drive, hence in so that power consumption is larger, there is larger energy consumption, cost is higher.
The content of the invention
There is provided a kind of a kind of inertia-type fluid conveying boosting method and its device simple in construction, energy-conserving and environment-protective for the big defect of power consumption when the purpose of the present invention is intended to overcome existing water pump or the air pump are compressed to fluid.
Therefore, the present invention uses following technical scheme:A kind of inertia-type fluid pressurized carrying method, use a container containing fluid, two through holes being spaced a distance are set on container as fluid input port and fluid outlet, fluid input port and fluid outlet all set the unidirectional input and output flowing of unidirectional valve controls fluid, container vibration is driven using vibratory drive mechanism, make the fluid direction of motion alternate change in container intracavity, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, realize the conveying supercharging of fluid.
Multiple described containers are sequentially connected by way of series connection, fluid input port on latter container is connected with the fluid outlet on previous container, make to be interconnected between each container, and the flow direction of the check valve is consistent, fluid of the container in vibration processes in container is pressurized step by step when circulating each container successively, realizes the conveying supercharging of fluid.
Multiple described containers are attached on the direction of vibration of container by way of in parallel, it is separate between each container, fluid outlet on each described container is interconnected by pipeline, exported after fluid outlet output of fluid of the container in vibration processes in container from each container and the pipeline convergence by connection, the conveying capacity of fluid is added, the conveying supercharging of fluid is realized.
Realize a kind of inertia-type fluid conveying supercharging device of inertia-type fluid pressurized carrying method, including vacuum tightness cavity, fluid pressurized mechanism and vibratory drive mechanism, the both sides of fluid pressurized mechanism are vacantly installed on by spring supporting in described vacuum tightness cavity respectively, fluid pressurized mechanism can move up and down with spring in the axial direction of spring, fluid pressurized mechanism is sequentially connected in series the container being fixedly connected including multiple, the two ends of each container are respectively arranged with fluid input port and fluid outlet, the fluid input port of the container of one end is connected by elastic fluid delivery pipe with fluid-storing container respectively with the fluid outlet of the container of the other end, the fluid input port of each container of intermediate arrangement is connected with the fluid outlet of its previous container, check valve is provided with the fluid input port and fluid outlet of each container, and the flow direction of each check valve is consistent, described vibratory drive mechanism is connected with the fluid pressurized mechanism and drives each container of fluid pressurized mechanism of reciprocating vibration, make the fluid direction of motion alternate change in container intracavity, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, realize the conveying supercharging of fluid.
Realize another inertia-type fluid conveying supercharging device of inertia-type fluid pressurized carrying method, including vacuum tightness cavity, fluid pressurized mechanism and vibratory drive mechanism, the both sides of fluid pressurized mechanism are vacantly installed on by spring supporting in described vacuum tightness cavity respectively, fluid pressurized mechanism can move up and down with spring in the axial direction of spring, fluid pressurized mechanism is included in the multiple containers that parallel connection is fixedly connected in the axial direction of the spring, the two ends of each container are respectively arranged with fluid input port and fluid outlet, the fluid input port of each container is connected by elastic fluid delivery pipe with fluid-storing container, the fluid outlet of each container is connected by the fluid delivery tube of elasticity with fluid-storing container, check valve is provided with the fluid input port and fluid outlet of each container, and the flow direction of each check valve is consistent, described vibratory drive mechanism is connected with the fluid pressurized mechanism and drives each container of fluid pressurized mechanism of reciprocating vibration, make the fluid direction of motion alternate change in container intracavity, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, realize the conveying supercharging of fluid.
Described booster transportation apparatus also includes surge tank, surge tank includes sealed hollow vessel, tank inner chamber is vertically disposed with air chamber and fluid chamber, the bottom of tank body is provided with import, the fluid outlet of each described container is connected by the fluid delivery tube of elasticity with the import, and air valve is provided with the top of tank body and is connected with air chamber, outlet is additionally provided with described tank body, outlet is not connected with the air chamber, and outlet is connected by pipeline with fluid-storing container.
Described vibrating mechanism includes pitman, permanent magnet and coil block, pitman one end is fixedly connected on described fluid pressurized mechanism, described permanent magnet is fixedly connected on the other end of pitman, described coil block includes the first coil as signal source and the second coil as power source, second coil is connected by a process circuit with external power supply, it is opposite with permanent magnet pole after second coil electricity, the induced current signal enabling process circuit that first coil is produced, the second coil is transported to by the electric current of external power supply by amplification rectification.
Described first coil and the second coil is set up in parallel in the axial direction, and pitman drives described permanent magnet to be walked in first coil and the second coil.
Described first coil is set around outside described permanent magnet, and the second described coil is set around the outside of described first coil, and described pitman drives described permanent magnet axially to be walked in first coil.
Each described corresponding lumenal cross-section in container upper fluid input port is more than the corresponding lumenal cross-section of fluid outlet.
The present invention can reach following beneficial effect:By the way that container is placed in vacuum tightness cavity, container vibration is driven using vibratory drive mechanism, the unidirectionally controlled of extruding that fluid produces under effect of inertia and check valve fluid flow direction is made by the change vibrated to the fluid direction of motion in container intracavity, realize the conveying supercharging of fluid, vibratory drive mechanism only needs small electric energy to maintain the of reciprocating vibration of container during work, power consumption is small, substantially increases energy-saving effect.
Brief description of the drawings
Fig. 1 is the schematic diagram of embodiments of the present invention one.
Fig. 2 is the schematic diagram of embodiments of the present invention two.
Embodiment
The embodiment to the present invention is described in detail below in conjunction with the accompanying drawings.
Embodiment one,
The present invention is sequentially connected using multiple containers 3 by way of series connection, each containing fluid of container 3, particularly gas, two through holes being spaced a distance are set on container 3 as fluid input port and fluid outlet, fluid input port and fluid outlet all set the unidirectional input and output flowing of unidirectional valve controls fluid, fluid input port on latter container 3 is connected with the fluid outlet on previous container 3, vibrated using vibratory drive mechanism driving container 3, make the fluid direction of motion alternate change in the inner chamber of container 3, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, fluid of the container in vibration processes in container is pressurized step by step when circulating each container 3 successively, realize the conveying supercharging of fluid.
Realize the inertia-type fluid conveying supercharging device of this method,Including vacuum tightness cavity 4,Fluid pressurized mechanism and vibratory drive mechanism,The both sides of fluid pressurized mechanism support hanging be installed in described vacuum tightness cavity 4 by spring 5 respectively,Fluid pressurized mechanism can move up and down with spring 5 in the axial direction of spring 5,Fluid pressurized mechanism is sequentially connected in series the container 3 being fixedly connected including multiple,The two ends of each container 3 are respectively arranged with fluid input port 9 and fluid outlet 11,Each corresponding lumenal cross-section in 3 upper fluid input port of container 9 is more than the corresponding lumenal cross-section of fluid outlet 11,The fluid input port 9 of the container 3 of one end is connected by elastic fluid delivery pipe 2 with fluid-storing container 1 respectively with the fluid outlet 11 of the container 3 of the other end,The fluid input port 9 of each container of intermediate arrangement is connected with the fluid outlet 11 of its previous container 3,Check valve is provided with the fluid input port 9 and fluid outlet 11 of each container 3,And the flow direction of each check valve is consistent,Described vibrating mechanism includes pitman 8,Permanent magnet 10 and coil block,The one end of pitman 8 is fixedly connected on described fluid pressurized mechanism,Described permanent magnet 10 is fixedly connected on the other end of pitman 8,Described coil block includes the first coil 7 as signal source and the second coil 6 as power source,The coil 6 of first coil 7 and second is set up in parallel in the axial direction,Pitman 8 drives described permanent magnet 10 to be walked in the coil 6 of first coil 7 and second,Second coil 6 is connected by a process circuit with external power supply,Second coil 6 is opposite with permanent magnet pole after being powered,The induced current signal enabling process circuit that first coil 7 is produced,The electric current of external power supply is transported to the second coil 6 by amplification rectification,So as to drive each container 3 of fluid pressurized mechanism of reciprocating vibration,Make the fluid direction of motion alternate change in the inner chamber of container 3,The extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled,Realize the conveying supercharging of fluid.
Embodiment two,
The present invention is fixedly connected using multiple separate containers 22 by way of in parallel, each containing fluid of container 22, particularly liquid, two through holes being spaced a distance are set on container 22 as fluid input port 23 and fluid outlet 26, fluid input port 23 and fluid outlet 26 all set the unidirectional input and output flowing of unidirectional valve controls fluid, it is of reciprocating vibration using vibratory drive mechanism driving container, each container 22 is set up in parallel on the direction of vibration, fluid outlet 26 on each described container 22 is interconnected by pipeline, exported after the pipeline convergence that the fluid outlet 26 of each container is exported and passes through connection, fluid direction of motion alternate change of the container in vibration processes in container, the extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled, add the conveying capacity of fluid, realize the conveying supercharging of fluid.
Realize a kind of inertia-type fluid conveying supercharging device of this method,Including vacuum tightness cavity 11,Fluid pressurized mechanism,Vibratory drive mechanism and surge tank 16,The both sides of fluid pressurized mechanism support hanging be installed in described vacuum tightness cavity 11 by spring 25 respectively,Fluid pressurized mechanism can move up and down with spring 25 in the axial direction of spring 25,Fluid pressurized mechanism is included in the multiple containers 22 that parallel connection is fixedly connected in the axial direction of the spring 25,The two ends of each container 22 are respectively arranged with fluid input port 23 and fluid outlet 26,Each corresponding lumenal cross-section in 22 upper fluid input port of container 23 is more than the corresponding lumenal cross-section of fluid outlet 26,The fluid input port 23 of each container 23 is connected by the fluid delivery tube 12 and surge tank 16 of elasticity with fluid-storing container 14,Described surge tank 16 includes sealed hollow vessel,Tank inner chamber is vertically disposed with air chamber and fluid chamber,The bottom of tank body is provided with import 13,The fluid outlet 26 of each described container 22 is connected by the fluid delivery tube 12 of elasticity with the import 13,Air valve 17 is provided with the top of tank body to connect with air chamber,Outlet 15 is additionally provided with described tank body,Outlet 15 is not connected with the air chamber,Outlet 15 is connected by pipeline with fluid-storing container 14,Check valve is provided with the fluid input port 23 and fluid outlet 26 of each container 22,And the flow direction of each check valve is consistent,Described vibrating mechanism includes pitman 20,Permanent magnet 18 and coil block,The one end of pitman 20 is fixedly connected on described fluid pressurized mechanism,Described permanent magnet 18 is fixedly connected on the other end of pitman 20,Described coil block includes the first coil 19 as signal source and the second coil 21 as power source,The coil 21 of first coil 19 and second is set up in parallel in the axial direction,Pitman drives described permanent magnet to be walked in the coil 21 of first coil 19 and second,Second coil 21 is connected by a process circuit with external power supply,Second coil leads to opposite with permanent magnet pole after 21 electricity,The induced current signal enabling process circuit that first coil 19 is produced,The electric current of external power supply is transported to the second coil 21 by amplification rectification,So as to drive each container 22 of fluid pressurized mechanism of reciprocating vibration,Make the fluid direction of motion alternate change in the inner chamber of container 22,The extruding that is produced by fluid under effect of inertia and check valve fluid flow direction it is unidirectionally controlled,Realize the conveying supercharging of fluid.
In above-mentioned embodiment one and two, described first coil and the second coil can also be set around the outside of permanent magnet successively, and connecting plate drives permanent magnet synchronously to be walked in first coil and the second coil.
Claims (10)
1. a kind of inertia-type fluid pressurized carrying method, it is characterised in that:This method contains stream using a container
Two through holes being spaced a distance are set to be exported as fluid input port and fluid on body, container
Mouth, fluid input port and fluid outlet all set the unidirectional input and output of unidirectional valve controls fluid
Flowing, drives container vibration using vibratory drive mechanism, makes the fluid direction of motion in container intracavity
Alternate change, the extruding produced by fluid under effect of inertia and check valve fluid flow direction
It is unidirectionally controlled, realize fluid conveying supercharging.
2. a kind of inertia-type fluid pressurized carrying method according to claim 1, it is characterised in that:It is many
Individual described container is sequentially connected by way of series connection, and the fluid input port on latter container is with before
Fluid outlet connection on one container, makes to be interconnected between each container, and the check valve
Flow direction it is consistent, fluid of the container in vibration processes in container is in each container that circulates successively
When be pressurized step by step, realize fluid conveying supercharging.
3. a kind of inertia-type fluid pressurized carrying method according to claim 1, it is characterised in that:It is many
Individual described container is attached on the direction of vibration of container by way of in parallel, each container
Between it is separate, fluid outlet on each described container is interconnected by pipeline, container
Fluid in vibration processes in container exports from the fluid outlet of each container and passes through connection
Pipeline convergence after export, add the conveying capacity of fluid, realize fluid conveying supercharging.
4. realizing a kind of inertia-type fluid pressurized conveying device of method as claimed in claim 2, its feature exists
In:Described booster transportation apparatus includes vacuum tightness cavity, fluid pressurized mechanism and vibratory drive
Mechanism, it is close that the both sides of fluid pressurized mechanism are vacantly installed on described vacuum by spring supporting respectively
In closed chamber body, fluid pressurized mechanism can move up and down with spring in the axial direction of spring, fluid pressurized
Mechanism is sequentially connected in series the container being fixedly connected including multiple, and the two ends of each container are respectively arranged with stream
The stream of body input port and fluid outlet, the fluid input port of the container of one end and the container of the other end
Body delivery outlet is connected by elastic fluid delivery pipe with fluid-storing container respectively, intermediate arrangement it is each
The fluid input port of individual container is connected with the fluid outlet of its previous container, the fluid of each container
Check valve, and the flow direction one of each check valve are provided with input port and fluid outlet
Cause, described vibratory drive mechanism is connected with the fluid pressurized mechanism and drives fluid pressurized mechanism
Each container it is of reciprocating vibration, make the fluid direction of motion alternate change in container intracavity, pass through stream
Extruding and unidirectionally controlled, the realization in check valve fluid flow direction that body is produced under effect of inertia
The conveying supercharging of fluid.
5. realizing a kind of inertia-type fluid pressurized conveying device of method as claimed in claim 3, its feature exists
In:Described booster transportation apparatus includes vacuum tightness cavity, fluid pressurized mechanism and vibratory drive
Mechanism, it is close that the both sides of fluid pressurized mechanism are vacantly installed on described vacuum by spring supporting respectively
In closed chamber body, fluid pressurized mechanism can move up and down with spring in the axial direction of spring, fluid pressurized
Mechanism is included in the multiple containers that parallel connection is fixedly connected in the axial direction of the spring, the two of each container
End is respectively arranged with fluid input port and fluid outlet, and the fluid input port of each container passes through
Elastic fluid delivery pipe is connected with fluid-storing container, and the fluid outlet of each container passes through bullet
The fluid delivery tube of property is connected with fluid-storing container, and the fluid input port and fluid of each container are defeated
Check valve is provided with outlet, and the flow direction of each check valve is consistent, described vibration is driven
Motivation structure is connected with the fluid pressurized mechanism and drives each container of fluid pressurized mechanism reciprocal
Vibration, makes the fluid direction of motion alternate change in container intracavity, by fluid under effect of inertia
The extruding of generation and check valve fluid flow direction it is unidirectionally controlled, realize that the conveying of fluid increases
Pressure.
6. a kind of inertia-type fluid pressurized conveying device according to claim 5, it is characterised in that:Institute
The booster transportation apparatus stated also includes surge tank, and surge tank is included in sealed hollow vessel, tank body
Chamber is vertically disposed with air chamber and fluid chamber, and the bottom of tank body is provided with import, each described appearance
The fluid outlet of device is connected by the fluid delivery tube of elasticity with the import, and the top of tank body is set
There is air valve to be connected with air chamber, outlet, outlet and the gas are additionally provided with described tank body
Chamber is not connected, and outlet is connected by pipeline with fluid-storing container.
7. a kind of inertia-type fluid pressurized conveying device according to claim 4,5 or 6, its feature exists
In:Described vibrating mechanism includes pitman, permanent magnet and coil block, and pitman one end is fixed
Described fluid pressurized mechanism is connected to, described permanent magnet is fixedly connected on the another of pitman
End, described coil block includes the first coil as signal source and the second line as power source
Circle, the second coil is connected by a process circuit with external power supply, after second coil electricity and
Permanent magnet pole is opposite.
8. a kind of inertia-type fluid pressurized conveying device according to claim 7, it is characterised in that:Institute
The first coil and the second coil stated are set up in parallel in the axial direction, and pitman drives described permanent magnet
Walked in first coil and the second coil.
9. a kind of inertia-type fluid pressurized conveying device according to claim 7, it is characterised in that:Institute
The first coil stated is set around outside described permanent magnet, and the second described coil is set around described
The outside of first coil, described pitman drives described permanent magnet axially to be worn in first coil
OK.
10. a kind of inertia-type fluid pressurized conveying device according to claim 9, it is characterised in that:Institute
It is corresponding that each the corresponding lumenal cross-section in container upper fluid input port stated is more than fluid outlet
Lumenal cross-section.
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CN201610059427.8A CN106996398A (en) | 2016-01-25 | 2016-01-25 | A kind of inertia-type fluid conveying boosting method and its device |
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CN201610059427.8A CN106996398A (en) | 2016-01-25 | 2016-01-25 | A kind of inertia-type fluid conveying boosting method and its device |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110857751A (en) * | 2018-08-23 | 2020-03-03 | 中国石油天然气股份有限公司 | Gas storage device |
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2016
- 2016-01-25 CN CN201610059427.8A patent/CN106996398A/en active Pending
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110857751A (en) * | 2018-08-23 | 2020-03-03 | 中国石油天然气股份有限公司 | Gas storage device |
CN110857751B (en) * | 2018-08-23 | 2021-05-28 | 中国石油天然气股份有限公司 | Gas storage device |
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Application publication date: 20170801 |